Rope management device

ABSTRACT

A rope management device is provided that includes features allowing for transition from a rope clamping position to a rope unclamped position when under load. Included is a teeter bar having a pivot axis allowing for application of friction on a section of rope to hold a load in place and then when rope is pulled through the device the load is maintained while allowing the teeter bar to pivot to eliminate friction on the rope.

CLAIM FOR BENEFIT OF EARLIER FILING DATE

This application claims the benefit of U.S. Provisional Application No. 61/214,287 filed on 23 Apr. 2009 and entitled “ROPE MANAGEMENT DEVICE”. This utility application has the same subject matter and title as the aforesaid Provisional Application.

BACKGROUND

The background of the invention will be discussed in two parts.

FIELD OF THE INVENTION

The present invention relates to a rope management device and in particular to a device for ascending and descending a rope without the assistance of a belayer and that can be changed from a clamping device to an unclamping device under load.

RELATED ART

In U.S. Pat. No. 6,899,203 issued on 31 May 2005 to Perry L. Everett et al., and in U.S. Pat. No. 7,533,871 issued on 19 May 2009 to Perry L. Everett et al., there is shown and described rope climbing apparatus that provides a simple and convenient way to ascend and descend a rope without using a belayer. The present invention provides an easier and smoother transition from a rope clamping position to a rope unclamping position, thus conveniently providing an even more effective rope climbing device.

SUMMARY

A rope management device is provided that includes features allowing for transition from a rope clamping position to a rope unclamped position when under load. Included is a teeter bar having a pivot axis allowing for application of friction on a section of rope to hold a load in place and then when rope is pulled through the device the load is transferred within the device and allows the teeter bar to pivot about another axis to eliminate friction between the rope and clamping surfaces. The device can function with a double rope technique system as well as a belay device.

DRAWINGS

FIG. 1 is an exploded perspective diagram illustrating the manner in which the components of the present invention are assembled in relationship to each other according to an embodiment of the invention;

FIG. 2 is a perspective view of the assembled device of FIG. 1 as viewed looking toward the access plate;

FIG. 3 is a perspective view of the opposite side on the assembled device of the invention of FIG. 1 as viewed looking toward the base plate;

FIG. 4 is a perspective side view of the assembled device of FIG. 1;

FIG. 5 is a cross-sectional view of the invention taken along lines 5-5 of FIG. 4;

FIG. 6A illustrates operation of the device of the invention approaching a clamping position under load; and

FIG. 6B illustrates operation of the device of the invention wherein the device is in an unclamping position.

LIST OF REFERENCE NUMERALS IN THE APPLICATION

A listing of the reference numerals, in which like reference numerals refer to like elements in the several views, with a brief description of their function, is as follows:

-   -   101. General designation of the device of the invention     -   1. Base plate     -   1 a. Base plate attachment hole     -   1 b. Base plate pivot hole     -   1 c. Base plate fastener hole for fastener 2 c     -   1 d. Base plate fastener hole for fastener 3 c     -   1 e. Base plate hole for stop 8     -   1 f. Base plate hole for stop 7     -   1 g. Base plate fastener hole for stop bolt 10 f     -   1 h. Base plate fastener hole for stop bolt 10 f     -   1 i. Base plate fastener hole for stop bolt 10 f     -   1 j. Base plate fastener hole for stop bolt 10 f     -   2. Bollard for attachment to base plate 1 by means of fastener 2         c     -   2 a. Threaded fastener hole for receiving fastener 2 c and stop         6     -   2 b. Fastener hole for receiving fastener 4 b     -   2 c. Threaded fastener for connection through fastener hole 1 c         to side B of bollard 2     -   3. Bollard for attachment to base plate 1 by means of fastener 3         c     -   3 a. Threaded fastener hole for receiving fastener 3 c     -   3 b. Fastener hole for receiving fastener 5 b     -   3 c. Fastener for connection through pivot hole 9 c and base         plate hole 1 d to side B of bollard 3     -   4. Wear sleeve for receiving bollard 2     -   4 a. Fastener hole for receiving fastener 4 b     -   4 b. Threaded fastener for connection through fastener hole 4 a         of wear sleeve 4 into fastener hole 2 b of bollard 2     -   5. Wear sleeve for receiving bollard 3 a.     -   5 a. Fastener hole for receiving fastener 5 b     -   5 b. Threaded fastener for connection through fastener hole 5 a         of wear sleeve 5 into fastener hole 3 b of bollard 3     -   6. Stop for threading into hole 2 a of side A of bollard 2     -   7. Stop for threading into hole 1 f of side A of base plate 1     -   8. Stop for insertion into hole 1 e of side B of base plate 1     -   9. Cam     -   9 a. Cam fastener hole     -   9 b. Cam fastener hole     -   9 c. Cam pivot hole     -   9 d. Fastener hole     -   9 e. Spring     -   9 f. Control screw     -   10. Handle     -   10 a. Handle fastener hole for receiving bolt 10 c     -   10 b. Handle fastener hole for receiving bolt 10 d     -   10 c. Handle fastener bolt     -   10 d. Handle fastener bolt     -   10 e. Fastener hole     -   10 f. Governor stop bolt     -   11. Teeter bar     -   11 a. Teeter bar attachment hole     -   11 b. Teeter bar pivot hole     -   11 c. Teeter bar fastener hole     -   11 d. General designation for teeter bar friction brake     -   11 e. General designation for teeter bar fairlead     -   12. Bearing     -   12 a. Bearing fastener hole     -   13. Access plate     -   13 a. Access plate attachment hole     -   13 b. Access plate pivot hole     -   13 c. General designation for access plate catch     -   14. Fastener for insertion into fairlead fastener hole 11 c     -   15. Fastener for insertion through pivot holes 1 b and 13 b,         abuts friction brake 11 d     -   15 a. Nut for receiving fastener 15 on side B of access plate 13

DESCRIPTION

The present invention provides a different embodiment of the disclosures of U.S. Pat. No. 6,899,203 issued on 31 May 2005 to Perry L. Everett et al. and of U.S. Pat. No. 7,533,871 issued on 19 May 2009 to Perry L. Everett et al., which patents are incorporated herein by reference.

FIG. 1 is an exploded perspective diagram illustrating the manner in which the components of the present invention, generally designated 110, are assembled in relationship to each other. As illustrated, the major components include a base plate 1, access plate 13, teeter bar 11, cam 9, handle 10, and bollards 2 and 3. Also included are bollard wear sleeves 4 and 5, bearing 12, stops 6, 7, and 8, and pivot axis fasteners 3 c, 14 and 15. Further included are miscellaneous fasteners 2 c, 4 b, 5 b, 10 c, 10 d and 15 a.

FIG. 2 is a perspective view of the assembled device of FIG. 1 as viewed looking toward the access plate, FIG. 3 is a perspective view of the opposite side on the assembled device of the invention of FIG. 1 as viewed looking toward the base plate, FIG. 4 is a perspective side view of the assembled device of FIG. 1, and FIG. 5 is a cross-sectional view of the invention taken along lines 5-5 of FIG. 4. After assembly of the device 110 as indicated in FIGS. 1-4, there are three component pivot axis' designated pivot axis 1, pivot axis 2 and pivot axis 3. Pivot axis 1 is defined by aligned pivot holes 1 b, 11 b and 13 b secured by fastener 15 and nut 15 a, pivot axis 2 defined by pivot hole 11 c and secured by fastener 15, and pivot axis 3 defined by aligned pivot holes 9 c and 1 d and secured to bollard 3 by fastener 3 c. There are two rope attachment points, attachment point 1 at teeter bar attachment hole 11 a, and attachment point 2 defined by aligned base plate attachment hole 1 a and access plate attachment hole 13 a.

As indicated in the drawings the components of the invention and their assembly are described as follows:

a base plate 1 having ten holes, an attachment hole 1 a, pivot hole 1 b, and six fastener holes 1 c, 1 d, 1 e, 1 f, 1 g, 1 h, 1 i and 1 j; hole 1 c for receiving threaded fastener screw 2 c therethrough to permanently fasten bollard 2 to side A of base plate 1 by engagement with threaded hole 2 a; hole 1 d for receiving fastener bolt 3 c therethrough to fasten bollard 3 to side A of base plate 1, holes 1 e, 1 g, 1 h, 1 i, and 1 j for selectively affixing stop 8, and threaded hole 1 f for permanently affixing threaded stop 7;

bollards 2 and 3 include fastener holes 2 a and 3 a, respectively, for receiving securing fasteners 2 c and 3 c, respectively, to affix bollards 2 and 3 to base plate 1, and replaceable wear sleeves 4 and 5 secured by screws 4 b and 5 b, respectively, threaded hole 2 a also permanently affixing threaded stop 6 to the bottom of bollard 2;

a cam 9 having a pivot hole 9 c for receiving threaded fastener 3 c therethrough after which threaded fastener 3 c mates with threaded holes 1 d and 3 a to secure bollard 3 to side A of base plate 1 and thereby define pivot axis 3, and fastener holes 9 a and 9 b for securing handle 10 to side B of cam 9 by means of fastener bolts 10 c and 10 b, respectively, and fastener hole 9 d for securing spring 9 c by means of fastener screw 9 f;

a teeter bar 11 pivotally mounted between base plate 1 and access plate 13 by threaded fastener 15 which transits pivot holes 1 b, 11 b and 13 b to terminate in nut 15 a to thereby define pivot axis 1, attachment hole 11 a defining attachment point 1, a friction brake generally designated 11 d, and a fairlead generally designated 11 e having a fastener hole 11 c;

bearing 12 having hole 12 a for fixedly receiving a first end of fastener 14, the second end of fastener 14 fixedly received by teeter bar hole 11 c, this arrangement allowing bearing 12 to remain in contact with cam 9, the combination of bearing 12, fastener 14 and hole 11 c defining pivot axis 2;

access plate 13 having rope attachment hole 13 a, pivot hole 13 b for receiving bolt 15, pivot hole 13 b co-acting with fastener 15, pivot hole 11 b to rotatably affix teeter bar 11 to side B of access plate 13, hole 13 a co-acting with hole 1 a to define rope attachment point pivot axis 2, and catch 13 c configured for co-acting with threaded stop 6;

handle 10 permanently affixed to cam 9 by threaded fasteners 10 c and 10 d transiting holes 10 a and 10 b, respectively, to engage threaded holes 9 a and 9 b, respectively.

FIGS. 6A and 6B illustrate an operational configuration for the invention. FIG. 6 a shows tether line 108 attached at one end to attachment point 1 defined by hole 1 a and the other end to security belt 107 shown to be attached to a fellow climber. Rope 105 is shown attached at one end to attachment point 2 defined by hole 13 a and then passed around an anchor 103 and then between base plate 1 a and access plate 13 positioned to pass bollards 2 and 3 and then around fairlead 11 e and out for manual control by the device operator. With this configuration it is possible for the operator, by pulling or letting off on the rope 105, to control the distance between pivot axis 3 (hole 1 d of base plate 1) and pivot axis 2 (hole 11 c of teeter bar 11) to thereby control the distance between bollard 3 and friction brake 11 d. With this control the device 101 can be operated to go from a rope clamping state to an unclamping state even when under load.

As shown in FIG. 1, teeter bar 11 is pivotally mounted between base plate 1 and access plate 13 on pivot axis 1, thus allowing teeter bar 11 to teeter about pivot axis 1. As indicated in FIGS. 6A and 6B, when a load is applied to attachment point 1 teeter bar 11 teeters about pivot axis 1 to move fairlead 11 e toward bollard 3 and thus moving pivot axis 2 and pivot axis closer together to apply clamping pressure and friction on a section of rope 105 between wear sleeve 5 of bollard 3 and friction brake 11 d of teeter bar 11. As the applied load increases, applied clamping pressure and friction increases and holds the load by preventing movement of rope 105 through the device 101.

As is evident from review of the figures, pivot hole 11 b is in an off center location between attachment hole 11 a and fairlead 11 e of teeter bar 11 which provides a leverage advantage. The distance between fairlead 11 e and pivot axis 1 is greater than the distance between attachment hole 11 a and pivot axis 1. This leverage advantage makes it possible to more easily pull rope 105 through device 101. As rope 105 is pulled down against fairlead 11 e teeter bar 11 teeters on pivot axis 1 moving pivot axis 2 and pivot axis 3 further apart thus eliminating clamping pressure and friction on rope 105 between wear sleeve 5 of bollard 3 and friction brake 11 d of teeter bar 11. This unclamping action allows rope 105 to be pulled through device 101, down across fairlead 11 e moving device 101 closer to anchor 103.

In operation of the device 101, co-action between handle 10, cam 9 and bearing 12 provides a mechanical advantage in that this co-action makes it possible to more easily control the distance between pivot axis 2 and pivot axis 3. This allows a controlled distance between wear sleeve 5 and friction brake 11 d which makes it possible for rope management device 101 to go from a rope clamping position to a rope unclamping position even when under load. As handle 10 and cam 9 are turned counter clockwise on pivot axis 3, bearing 12 follows cam 9 to move pivot axis 2 and pivot axis 3 further apart thereby reducing clamping pressure and friction on rope 105 between wear sleeve 5 of bollard 3 and friction brake 11 d of teeter bar 11. This unclamping action allows rope 105 to slip through device 101 at a controlled speed moving device 101 further from anchor 103.

Further, threaded fastener hole 9 d of cam 9, when receiving threaded governor control screw 9 f through governor spring 9 e together with base plate fastener holes 1 g, 1 h, 1 i, 1 j and governor stop bolt 10 f, provides a variable position stop. This provides means for limiting the descent speed of device 101 by limiting how far handle 10 and cam 9 are allowed to turn counter-clockwise before being stopped by governor stop bolt 10 f and governor control screw 9 f.

Although the present invention has been described with reference to an illustrated and described embodiment, other modifications and embodiments can be devised by those skilled in the art that would fall within the spirit and scope of the invention. 

1. A rope management device comprising; a base plate 1 having ten holes, an attachment hole 1 a, pivot hole 1 b, and six fastener holes 1 c, 1 d, 1 e, 1 f, 1 g, 1 h, 1 i and 1 j; hole 1 c for receiving threaded fastener screw 2 c therethrough to permanently fasten bollard 2 to side A of base plate 1 by engagement with threaded hole 2 a; hole 1 d for receiving fastener bolt 3 c therethrough to fasten bollard 3 to side A of base plate 1, holes 1 e, 1 g, 1 h, 1 i, and 1 j for selectively affixing stop 8, and threaded hole 1 f for permanently affixing threaded stop 7; bollards 2 and 3 include fastener holes 2 a and 3 a, respectively, for receiving securing fasteners 2 c and 3 c, respectively, to affix bollards 2 and 3 to base plate 1, and replaceable wear sleeves 4 and 5 secured by screws 4 b and 5 b, respectively, threaded hole 2 a also permanently affixing threaded stop 6 to the bottom of bollard 2; cam 9 having a pivot hole 9 c for receiving threaded fastener 3 c therethrough after which threaded fastener 3 c mates with threaded holes 1 d and 3 a to secure bollard 3 to base plate 1 and thereby define pivot axis 3, and fastener holes 9 a and 9 b for securing handle 10 to cam 9 by means of fastener bolts 10 c and 10 b, respectively; a teeter bar 11 pivotally mounted between base plate 1 and access plate 13 by threaded fastener 15 which transits pivot holes 1 b, 11 b and 13 b to terminate in nut 15 a to thereby define pivot axis 1, attachment hole 11 a defining attachment point 1, a friction brake generally designated 11 d, and a fairlead generally designated 11 e having a fastener hole 11 c; bearing 12 having hole 12 a for fixedly receiving a first end of fastener 14, the second end of fastener 15 fixedly received by teeter bar hole 11 c, this arrangement allowing bearing 12 to remain in contact with cam 9, the combination of bearing 12, fastener 14 and hole 11 c defining pivot axis 2; access plate 13 having attachment hole 13 a, pivot hole 13 b and generally designated catch 13 c, pivot hole 13 b co-acting with fastener 15 and pivot hole 11 b to rotatably affix teeter bar 11 to access plate 13, hole 13 a co-acting with hole 1 a to define attachment point 2, and catch 13 c configured for co-acting with threaded stop 6; handle 10 permanently affixed to cam 9 by threaded fasteners 10 c and 10 d transiting holes 10 a and 10 b, respectively, to engage threaded holes 9 a and 9 b, respectively.
 2. The rope management device in accordance with claim 1 wherein teeter bar 11 is pivotally mounted between base plate 1 and access plate 13 on pivot axis 1 thus allowing teeter bar 11 to teeter about pivot axis 1 such that when a load is applied to attachment point 1 teeter bar 11 teeters about pivot axis 1 to move fairlead 11 e toward bollard 3 thus moving pivot axis 2 and pivot axis closer together to apply clamping pressure and friction on a section of rope 105 between wear sleeve 5 of bollard 3 and friction brake 11 d of teeter bar 11 whereby as the applied load increases the corresponding clamping pressure and friction increases and holds the load by preventing movement of rope 105 through the device
 101. 3. The rope management device in accordance with claim 1 wherein threaded fastener hole 9 d of cam 9, when receiving threaded governor control screw 9 f through governor spring 9 e together with base plate fastener holes 1 g, 1 h, 11, 1 j and governor stop bolt 10 f, provides a variable position stop for limiting the descent speed of device 101 by limiting how far handle 10 and cam 9 are allowed to turn counter-clockwise before being stopped by governor stop bolt 10 f and governor control screw 9 f.
 4. The rope management device in accordance with claim 1 wherein handle 10, cam 9 and bearing 12 co-acts to provide means for controlling the distance between pivot axis 2 and pivot axis 3 thereby to allow a controlled distance between wear sleeve 5 and friction brake 11 d which provides for rope management device 101 to go from a rope clamping position to a rope unclamping position even when under load, handle 10 and cam 9 are turned counter clockwise on pivot axis 3, bearing 12 follows cam 9 to move pivot axis 2 and pivot axis 3 further apart thereby reducing clamping pressure and friction on rope 105 between wear sleeve 5 of bollard 3 and friction brake 11 d of teeter bar 11 whereby the resulting unclamping action allows rope 105 to slip through device 101 at a controlled speed and moving device 101 further from anchor
 103. 